Wireless infant health monitor

ABSTRACT

A system for wirelessly monitoring the health of an infant comprising a sensing module removably disposed within a wearable article. At least a portion of the sensing module can be in contact with an infant&#39;s foot. The sensing module can include a processing unit configured to receive and process health readings received by the sensing module. A wireless transmitter can also be in communication with the processing unit. The wireless transmitter can be configured to transmit the processed health readings to a receiving station. The receiving station can indicate an alarm if the processed health readings indicate a health trend that falls outside of a particular threshold.

CROSS-REFERENCE TO RELATED APPLICATIONS

The present application is a 35 U.S.C. §371 U.S. National of PCT PatentApplication No. PCT/US13/56511 filed Aug. 23, 2013, entitled “WirelessInfant Health Monitor,” which claims the benefit of U.S. ProvisionalApplication Ser. No. 61/798,642 entitled “Wireless Infant HealthMonitor”, filed on Mar. 15, 2013, U.S. Provisional Application Ser. No.61/693,267 entitled “SmartOx”, filed on Aug. 25, 2012, and U.S.Provisional Application Ser. No. 61/722,795 entitled “Owlet BabyMonitor”, filed on Nov. 6, 2012. The entire content of each of theaforementioned applications is incorporated by reference herein in itsentirety.

BACKGROUND OF THE INVENTION

1. The Field of the Invention

The present invention relates generally to infant monitoring equipment.

2. Background and Relevant Art

Every year thousands of babies die from Sudden Infant Death Syndrome(“SIDS”). Because the specific causes of SIDS may be difficult todetermine, many parents exert tremendous effort and worry checking onthe health of their baby. To aid parents in this effort, variousproducts for monitoring a baby's health, particularly while the baby issleeping, exist.

For example, many parents use an intercom system that allows them tolisten to their baby. In particular, a parent may be alerted to an issueif a long period time of passes without them hearing any noise over theintercom. One will understand, however, that this may not provide aparent with enough notice to intervene before a health issue becomesserious or fatal to the baby.

According, there are a number of problems in the art that can beaddressed.

BRIEF SUMMARY OF THE INVENTION

Implementations of the present invention overcome one or more of theforegoing or other problems in the art with systems, methods, andapparatus that wirelessly monitor the health of a baby. In particular,at least one implementation of the present invention monitors a child'sblood oxygen level and indicates an alert when an abnormal trend isidentified.

Implementations of the present invention include a system for wirelesslymonitoring the health of an infant. The system can comprise a sensingmodule removably disposed within a wearable article. At least a portionof the sensing module can be in contact with an infant's foot. Thesensing module can include a processing unit configured to receive andprocess health readings received by the sensing module. A wirelesstransmitter can also be in communication with the processing unit. Thewireless transmitter can be configured to transmit the processed healthreadings to a receiving station. The receiving station can indicate analarm if the processed health readings indicate a health trend thatfalls outside of a particular threshold.

Additional features and advantages of the invention will be set forth inthe description which follows, and in part will be obvious from thedescription, or may be learned by the practice of the invention. Thefeatures and advantages of the invention may be realized and obtained bymeans of the instruments and combinations particularly pointed out inthe appended claims. These and other features of the present inventionwill become more fully apparent from the following description andappended claims, or may be learned by the practice of the invention asset forth hereinafter.

BRIEF DESCRIPTION OF THE DRAWINGS

In order to describe the manner in which the above-recited and otheradvantages and features of the invention can be obtained, a moreparticular description of the invention briefly described above will berendered by reference to specific embodiments thereof, which areillustrated, in the appended drawings. It should be noted that thefigures are not drawn to scale, and that elements of similar structureor function are generally represented by like reference numerals forillustrative purposes throughout the figures. Understanding that thesedrawings depict only typical embodiments of the invention and are nottherefore to be considered to be limiting of its scope, the inventionwill be described and explained with additional specificity and detailthrough the use of the accompanying drawings in which:

FIG. 1 illustrates a schematic diagram of a system for monitoring thehealth of an infant in accordance with an implementation of the presentinvention;

FIG. 2A illustrates a wearable article in accordance with animplementation of the present invention;

FIG. 2B illustrates another view of the wearable article of FIG. 2A;

FIG. 2C illustrates the wearable article of FIG. 2A disposed on aninfant's foot;

FIG. 2D illustrates yet another view of the wearable article of FIG. 2A;

FIG. 3A illustrates a sensor module in accordance with an implementationof the present invention;

FIG. 3B illustrates another view of the sensor module of FIG. 3A;

FIG. 3C illustrate an implementation of a pulse oximeter of the presentinvention;

FIG. 3D illustrate another implementation of a pulse oximeter of thepresent invention;

FIG. 3E illustrates yet another implementation of a pulse oximeter ofthe present invention;

FIG. 4 depicts an implementation of a sensing module circuit board ofthe present invention;

FIG. 5 illustrates an implementation of a receiving station and animplementation of an accompanying receiving station cover;

FIG. 6 depicts a circuit board and display associated with animplementation of a receiving station;

FIG. 7 depicts a smart phone displaying an interface that is associatedwith the present invention;

FIG. 8 depicts a logical tree associated with an implementations of thepresent invention; and

FIG. 9 illustrates a schematic diagram of another implementation of asystem for monitoring the health of an infant.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Implementations of the present invention extend to systems, methods, andapparatus that wirelessly monitor the health of a baby. In particular,at least one implementation of the present invention monitors a child'sblood oxygen level and indicates an alert when an abnormal trend isidentified.

For example, FIG. 1 illustrates a schematic diagram of a system formonitoring the health of an infant in accordance with an implementationof the present invention. In particular, FIG. 1 depicts a sensing moduledisposed within a sock (shown by element 100) that is in communicationwith a receiving station 110. The receiving station 110 is in turn canbe in communication with an internet gateway 120 (e.g., a cable modem, arouter, a DSL modem, an Ethernet port, etc.). The internet gateway 120is shown communicating with a computerized device in this implementationa smart phone 130. The smart phone 130 can display data that wasoriginally gathered by the sensing unit (shown in element 100).

In at least one implementation, the sensing module 210 comprises a pulseoximeter 220 (shown in FIG. 3B) in communication with a processing unit250 (shown in FIG. 4). The pulse oximeter 220 can be positioned suchthat a sensing portion of the pulse oximeter 220 is in sufficientcontact with an infant's foot as to receive a pulse oximetry reading.The pulse oximeter 220 can then provide raw data pulse oximetry data tothe processing unit 250.

FIG. 1 depicts the sensing module disposed within a wearable article, inparticular, a sock 200. In at least one implementation, the sock 200consists of a “foot-wrap” or “sock” that wraps around the infant's footand/or ankle. The sock 200 can include the necessary electronics togenerate a pulse oximeter reading, for example from the infant'sfoot/ankle. The raw electrical signals can then be processed by theprocessing unit 250 on the sock to generate a heart rate value and anSpO2 or Oxygen value as well as other related data.

Once the processing unit 250 receives the raw pulse oximetry data, in atleast one implementation, the processing unit 250 processes the rawdata. In particular, the processing unit 250 can reformat the data froma raw form to a compressed form. The processing unit 250 can thenprovide the compressed data to the wireless transmitter 260 (shown inFIG. 4) that is also located within the sock.

The wireless transmitter 260 and the processing unit 250 can be locatedon a common circuit board. In some cases, processing the data at theprocessing unit before transmitting the data with the wirelesstransmitter 260 can result in significant battery savings, as comparedto transmitting the raw data. Additionally, processing the data with theprocessing unit 250 before transmitting the data can improve the dataintegrity and lower the error rate associated with the data.

Once the data has been processed and transmitted, a receiving station110 can receive and further analyze the data. In particular, thereceiving station 110 can process the data to identify negative healthtrends within the pulse oximetry data. For example, the receivingstation 110 can identify that the reported oxygen level of the infant isbelow a particular threshold. Additionally, in at least oneimplementation, the receiving station 110 can also identify if thesensing module 210 is running low on battery, if the transmitted signalstrength is low, or other functions that relate to the operation of thepresent invention.

If the receiving station 110 detects a potential negative trend in thepulse oximetry data or if the receiving station 110 detects a problemwithin the system (e.g., low battery, poor signal strength, etc.) thereceiving station 110 can provide an indication of the problem. Forexample, in at least one implementation, the receiving station 110 cansound an alarm, display a notification on a visual indicator located onthe receiving station 110, or otherwise send a message.

Further, in at least one implementation, the receiving station 110 candisplay the interpretations of the various data that it is receiving.For example, the receiving station 110 can show a graph tracking theoxygen level of an infant over time. Similarly, the receiving station110 can display information relating to the heart rate of the infant.Additionally, the receiving station 110 can display historicalinformation relating to the received data. For example, the receivingstation 110 can display an average oxygen level for the past hour. Ingeneral, the receiving station 110 can utilize the received informationto display a variety of useful data that would fall within the presentinvention.

In at least one implementation, after the receiving station 110 hasreceived and further analyze the data, the receiving station 110 cantransmit the data to an internet gateway 120, such as a wireless router.For example, the receiving station 110 can transmit to an internetgateway 120 over a Wi-Fi bridge. Once the data has been received by theinternet gateway 120, the data can be transmitted over the internet to aremote computing device 130 or web portal. In at least oneimplementation, the remote computing device 130 can be located withinthe same local network as the internet gateway 120 such that the data isonly transmitted locally and is not transmitted over the internet.Similarly, in at least one implementation, the wireless transmitter 260and the processing unit 250 can transmit information directly to theremote computing device 130 (e.g., a smart phone).

In particular, in at least one implementation, the data can betransmitted to a smart phone 130. In the case that a negative trend isidentified, the smart phone can sound an alert. Additionally, in atleast one implementation, the remote computing device 130 can access ahistorical record of health recordings. For example, a parent of aninfant can access a historical record of the infant's oxygen level andprovide the record to the infant's doctor. The accessed historicalrecord can be stored by the remote computing device, the receivingstation, or some other web based storage cache.

Similarly, the internet gateway 120 can transmit the data to a webportal. For example, the data can be transmitted to an associatedwebpage that is password protected. A user of the present invention canthen access the data through the associated webpage.

One will understand, that the embodiments described above are onlyexemplary and that a system of the present invention can comprise afewer number or a greater number of components. For example, in at leastone implementation, the present invention may only include the sock 200and sensing module 210 and the receiving station 110. In thisimplementation, the receiving station 110 could alert a user to anyinformation of interest, including negative health trends.

Similarly, in another implementation, the present invention can compriseonly the sock 200 and sensing module 210 and an internet gateway 120. Inthis implementation, the sock 200 and sensing module 210 can communicateto the internet gateway 120 through a wireless protocol. The internetgateway 120 can then transmit information to a remote computing device130 of interest.

Additionally, in at least one implementation, the present invention cancomprise only the sock 200 and sensing module 210. For example, in thisimplementation, the sensing module 210 can comprise an alarm, such thatwhen a negative health trend is detected, the sensing module 210 alertsa parent. Further, as mentioned above, the present invention cancomprise only the sock 200 and sensing module 210 and a remote computingdevice 130.

FIG. 2 illustrates a wearable article (e.g., a sock 200) and sensingmodule 210 that is configured to be disposed within the wearablearticle. In particular, FIG. 2 depicts an implementation of the presentinvention that comprises a sock 200 that is adapted to contain thesensing module 210. In at least one implementation, the sock 200 cancomprise a unique double-layer strapping mechanism and stretchablematerial that wraps around the infant's foot, creating a tight wrap,which will keep ambient light from interfering with signals generated byLEDs contained within the pulse oximeter sensor 220. For example, in atleast one implementation, the pulse oximeter sensor 220 is under theouter strap 230 and against the skin.

In at least one implementation, the sock 200 is configured for thesensing module 210 to be removed from the sock 200. For example, FIGS.2C and 2D shows the sensing module 200 disposed within a pocket 240within the sock 200. One will understand that the ability to remove thesensing module 210 from the sock 200 provides several benefits. Forexample, a sock 200 can easily be laundered by simply removing thesensing module 210 and washing the sock. Additionally, the same sensingmodule 210 can be used in socks 200 of different size, by simplyremoving the sensing module 210 from a sock 200 of a first size andinserting it into a sock 200 of a second size.

Additionally, in at least one implementation the sensing module 210 canbe housed in a water-resistant material. In particular, the housing canbe comprised of silicone or plastic. The housing may include are-sealable opening for access to an external cable for charging andserial communication. In another implementation, the electronics can becharged via an induction charging set-up.

FIGS. 2C and 2D illustrates an implementation of the wearable articlefrom FIGS. 2A and 2B being disposed upon an infant's foot. Inparticular, FIG. 2C depicts the sensing module 210 disposed within thesock 200 such that the sensing module 210 is primarily located aroundthe ankle of an infant. Placing the sensing module 210 around the ankleof the infant may have the benefits of providing greater security to thesensing module 210. For example, placing the sensing module 210 aroundthe infant's ankle may make it more difficult for the infant to kick thesensing module 210 off. Additionally, placing the sensing module 210around the infant's ankle may also provide more room for the sensingmodule 210 than if the module was placed around the child's foot.However, one will understand that in at least one implementation, thesensing module 210 can be placed such that the module is not on theinfant's ankle.

As depicted in FIG. 2C, the upper part of the sock can secure around theinfant's ankle. The lower part of the sock can secure around the infantsfoot. In at least one implementation, the straps on the sock can besecured by Velcro. Properly applying the straps of the present inventioncan create a strapping system that minimizes the infant's ability tokick the sock off.

In at least one implementation, the sock can also comprise a pouch 240configured to receive the sensing module 210. The pouch 240 can comprisea zipper that allows the pouch to securely open and close. Additionally,in at least one implementation, the pouch can comprise buttons, Velcro,snaps, or any other apparatus or useful combination of apparatuses toclose the pouch.

The sensing module 210, which is receivable into the pouch 240, cancomprise an outer layer of Velcro or other alignment feature. Inparticular, the Velcro or alignment feature can be attached to the pulseoximeter sensor 220 (shown in FIGS. 3A and 3B). This may allow the pulseoximeter sensor 220 to be securely fastened to outer strap 230, suchthat the pulse oximeter sensor 220 is secure and in close contact withthe skin of the infant's foot.

Additionally, in at least one implementation, the pulse oximeter sensor220 can be encased within a silicone-housed strap that contains theemitting and receiving electronics of the pulse oximetry system. Thesesensors can include a combination of LED lights and photoreceptors. Insome cases, multiple sensors can allow the pulse oximeter sensor 220 tocontinue to obtain strong pulse oximetry signals despite changes in footsize.

For example, a processing unit within the sensing module 210 may executean algorithm that finds the best possible combination of LED emittersand photoreceptors, which allows for the best possible pulse oximetryreadings. Additionally, the sensing module 210 can execute an algorithmthat optimizes the power usage of the LED emitters and photoreceptors.For example, FIGS. 3C-3E depict a multisensor mechanism for optimum spO2and pulse readings.

In some situations, the optimal location and combination of LED emittersand photoreceptors can change for example, as a baby's foot grows thelocation of the sensor on the baby's foot can change. To help improvethe quality of a sensor reading, in addition to using variouscombinations of LED emitters and photoreceptors, the sock 200 can alsoinclude design features in the strap that allow it to flex and moverelative to the electronics housing so that a user can place the strapat the optimum placing on the foot for the reading to occur.

The pulse oximeter sensor 220 that wraps around the infants foot may becomprised of a flexible PC board with attached LED lights andphotoreceptors (300, 310, 320, 330). This flexible PC board can behoused in a silicone or other flexible polymer. This housing can includea transparent portion and an opaque portion. Additionally, the pulseoximeter sensor 220 can also include a thermometer to monitor skintemperature, which can affect pulse oximetry readings. The thermometercan also be used to monitor and detect additional health trends withinan infant.

As mentioned above, the pulse oximeter sensor 220 can comprise a varietyof different LED and photoreceptor combinations (300, 310, 320, 330). Asa non-limiting example, the pulse oximeter sensor 220 can comprise onephotoreceptor or photodiode and one set of LED's (each at a uniqueoptical frequency), or one photoreceptor or photodiode and two sets ofLED's, two photoreceptors or photodiodes and one sets of LED's, or someother combination of multiple LED's and photoreceptors.

For example, FIG. 3C illustrates a depiction of an implementation of apulse oximeter sensor 220. In pulse oximetry, generally, two lightssources having different wavelengths are passed through an individual. Aphotoreceptor measures the transmitted wavelengths using known methodsand determines a blood oxygen level and a pulse. The depicted sensor 220comprises a plurality of sensor units 300, 310, 320, 330. In at leastone implementation, sensor units 300 and 310 can comprisesphotoreceptors and sensor units 320 and 330 can comprises LEDs.Specifically, sensor units 320 and 330 can comprise LED units capable oftransmitting light at two different wavelengths, for example, red andinfrared.

FIG. 3D illustrates a depiction of a cross section of a small foot 350enclosed within the pulse oximeter sensor 220. As depicted, sensor units300, 310, 320, and 330 are in contact with the surface of the foot atdifferent points around the circumference of the foot. In at least oneimplementation of the present invention, the sensing module 210 candetermine a combination of sensing units 300, 310, 320, 330 thatprovides a readable signal at an efficient power level. For example, inFIG. 3C sensing unit 300 and sensing unit 330 may have the strongestcommunication path 360 with each other and thus may generate thestrongest signal.

In contrast, FIG. 3E illustrates a depiction of a cross section of alarger foot 370. In this case, because the foot is larger, the sensingunits 300, 310, 320, 330 do not have the same alignment as in FIG. 3C.In particular, sensing unit 300 and sensing unit 320 may have thestrongest communication path 360, such that the sensing module 210 usesthese units 300, 320 for gathering pulse oximetry data.

Additionally, in at least one implementation, the active LED can bevaried to prevent too much heat from developing near the skin of aninfant. In particular, it may be possible for an LED to get hot enoughthat long exposure to the LED causes discomfort or even injury. Thus, inat least one implementation, the active LED can be varied such that nosingle LED is on long enough to generate excessive heat.

While the above described implementations, relied upon twophotoreceptors 300, 310 and two LED units 320, 330 the present inventioncan also be practiced with a variety of different sensor unitconfigurations. For example, in at least one implementation, more thanfour sensor units can be utilized to provide even greater granularity insensor unit selection. Further, in at least one implementation, therecan be more photoreceptors than LED units, or in contrast, more LEDunits than photoreceptors. Additionally, in at least one implementation,the sensing module 210 can determine that the strongest communicationpath 360 is not necessarily between LEDs that are opposing each other.In particular, in at least one implementation, the sensing module 210can determine that adjacent LEDs form the strongest communication path360.

Additionally, in at least one implementation, multiple photoreceptorscan be used to read from a single LED, or in contrast, a singlephotoreceptor can be used to read from multiple active LEDs. Forexample, the sensing module 210 can determine that activating three LEDsand receiving at two photoreceptors provides the necessary communicationstrength for a good reading, while using power most efficiently.Similarly, the sensing module 210 can determine that using a singlephotoreceptor reading from two LEDs provides the best reading for thelowest amount of power usage. Accordingly, in at least oneimplementation, the sensing module 210 can determine the ideal LED andphotoreceptor configuration by starting at a low (or lowest) powerconfiguration (e.g., one photoreceptor reading one LED) and progressingto a high (or highest) power configuration (e.g., all photoreceptorsreading all LEDs) to determine what configuration provides sufficientsignal strength for the least amount of power. In at least oneimplementation, efficient power usage is defined to mean using aconfiguration of LEDs that consumes the least amount of power whilestill providing a readable signal. Additionally, in at least oneimplementation, a readable signal is defined to mean a signal that theprocessing unit is able to interpret into health data.

In addition, the above-described implementations are not limited tobeing practiced by the sensing module 210. For example, in at least oneimplementation, the receiving station or a remote computing device candetermine the strongest pathway 360 between two sensor units.

The ability to selectively identify the strongest communication pathway360 between sensor units can improve the reliability of pulse oximetrydata. In particular, if the pulse oximetry sensor 220 moves after beingput on an infant's foot, a different strongest communication pathway 360can be identified to maintain the data quality. Additionally, in atleast one implementation, the ability to selectively identify astrongest communication pathway 360 can permit the pulse oximetry sensor200 to be used on a wide range of foot sizes.

FIG. 4 depicts an implementation of a portion of a processing unit 250.In particular, FIG. 4 depicts a processing unit 250 portion of a sensingmodule 210. The processing unit 250 can comprise means for processingpulse oximetry data on-site. Specifically, the processing unit canincludes all necessary means for processing and filtering the raw pulseoximeter data and relaying that data to a receiving station or othertypes of wireless transceivers. For example, the processing unit canconvert the raw data into a format that can be broadcast over aparticular wireless connection (e.g., Bluetooth, RF 915, etc.). One willunderstand, however, that various transmission formats are known in theart and any number and combination of known transmission formats can beused and remain within the scope of the present invention.

Additionally, the processing unit 250 can receive a raw data signal fromthe pulse oximeter sensor 210 and filter out both the AC and DCcomponent of the electrical signals sent from the photoreceptor. In atleast one implementation, the processing unit can also filter outunwanted noise from movement and external sources. As the processingunit processes and filters the received raw data the processing unit candetermine at least a blood oxygen level and a pulse.

In addition to the processing unit 250, in at least one implementation,the sensing module 210 can include at least one power source, such as abattery, that can power the sensing module 210. The battery can beremovable and/or rechargeable. In at least one implementation, thesensing module 210 can also include a visual indicator that indicateswhen the battery is low on power and need replacing.

The sensing module 210 can also include at least one accelerometer 262that can detect movement that could possibly disrupt the pulse oximeterreadings. For example, the normal movements of an infant may negativelyimpact the readings that are received by the pulse oximeter sensor.Detecting the movement can enable the processing unit 250 to compensatefor the movement, or in some cases, recognize a potential false alarm.This can allow for tagging unusual readings that are caused by movementto distinguish them from unusual readings due to abnormal heart ratesand other factors. For example, an infant's movements might shake thesensing module 210 loose causing the sensing module to report no pulseand low oxygen levels. However, instead of issuing an alarm, theaccelerometer 262 can detect movement and notify the sensing module 210that the no pulse and low oxygen levels are likely a false alarm.

Additionally, the accelerometer 262 can be used to determine a sleepingposition of the infant. It is believed that infants are most at risk forSIDs when they sleep with their face down. Accordingly, theaccelerometer 262 may be used to determine whether the infant's foot,and in turn body, is facing upwards or downwards. In determining theinfant's position the sensing module 210 may allow readings from theaccelerometer 262 to settle and persist for a particular amount of timeto avoid false alarms. In at least one implementation, the infant'sposition can be used in determining when to sound an alarm and whatalarm to sound. For example, an alarm may sound if an infant remainsface down for a particular period of time. Similarly, the position ofthe infant may be used to determine whether to elevate an alarm, or todetermine whether to signal a false alarm or an emergency alarm.

Additionally, a vibrator or alarm 264 can be disposed within the sensingmodule 210. The alarm or vibrator 264 can be used to alert a parent whena negative health trend is detected. Also, the vibrator or alarm 264 canbe used to stimulate breathing within the baby when a negative trend isdetected. In at least one implementation, the vibrator or alarm 264 onthe sensing module 210 only activates if an alarm on the receivingstation 110 is not available.

The sensing module 210 can also include at least one physicalcommunications port 266. The at least one communications port 266 can beused for recharging the battery within the sensing module, communicatingdata to the sensing module, updating software within the sensing module,or some other known function. Additionally, in at least oneimplementation, the sensing module 210 can physically connect to thereceiving station for recharging and communication purposes.

In at least one implementation, the sensing module 210 within the sock200 can be activated by the receiving station 110 by means of “wake-onradio”. Alternatively, the sensing module 210 can be activated bydetecting the levels of light being received by the photo-diodes to turnon the LED's when the sock is properly oriented on an infant's foot.

FIG. 5 illustrates an implementation of a receiving station 110 and animplementation of an accompanying receiving station cover 500. FIG. 5depicts a receiving station 110 comprising a plastic enclosure with anangled display for aesthetic appeal and functionality. The enclosure canbe designed to fit comfortably on a nightstand or counter. An angleddisplay may make it easy to see such that with a quick glance a parentcan see the oxygen and heart rate values and/or other importantnotifications.

FIG. 6 depicts another figure of an implementation of a receivingstation 110. The buttons 610 on the enclosure of the receiving stationmay be of the type shown in the drawing and the picture. The receivingstation 110 can receive the wireless transmission signal from a sensingmodule 210, or from multiple sensing modules 210 disposed withinmultiple socks attached to different infants. The receiving station 110can then display the data on an LCD display 620, including informationto distinguish between the potentially multiple sensing modules 210.

In at least one implementation, a user can configure the receivingstation's 110 response to a particular alarm or to alarms in general.For example, a user can silence a current alert being indicated by thereceiving station 110. Similarly, in at least one implementation, a usercan configure the receiving station 110 to only indicate an alarm ifcertain conditions are met. Further, a user can configure the receivingstation 110 to only communicate with certain means (e.g., audible alarm,vibration, visual indicator, etc.) and/or to only communicate throughcertain channels (e.g., only to remote devices, only to local devices,etc.).

Additionally, in at least one implementation, the receiving station 110can relay the data through a Wi-Fi/wireless bridge to the home or otherwireless routers, which then relay the data to a server or to anotherdevice on the network. The receiving station 110 can also comprisevarious LED lights for added clarity to the caregiver. In addition, anambient light sensor may also signal the receiving station 110 toautomatically dim its screen while in a dark room.

The receiving station 110 can also include a means of locally storingthe health data for later analysis, upload, and/or product verification.Further, in at least one implementation, the receiving station 110 canalso connect to other sensors such as a microphone, video camera,thermometer, or movement sensor/pad. Additionally, the receiving station110 can comprise the necessary transmission components to communicatewith the sensing module 210 (e.g., an RF 915 MHz receiver, Bluetooth)and the internet gateway (e.g., via a Wi-Fi bridge).

In addition, the receiving station 110 can comprise software configuredto manage the data received from the sensing module 210. In particular,the software can provide instructions to alert parents if there ispossible danger to their child. Since false alarms cause anxiety andunnecessary fear, however, in at least one implementation, the softwarecan include a delayed alarm system. Many infants naturally hold theirbreath for short periods of time, causing the blood oxygen concentrationto drop. Since this can be a normal occurrence, the receiving station110 software cannot only evaluate the current oxygen level but also anyupward and downward trends of the oxygen and heart rate values.

For example, in at least one implementation, the software can identifyan abnormal downward trend in the health data, and based on the trendsound an alarm. In contrast, in at least one implementation, thesoftware can identify a normal downward trend in the health data anddelay the alarm for a threshold time to determine if the health datawill return to normal levels. One will understand that identifyingtrends within the health data can help limit false alarms due to naturalevents.

FIG. 7 depicts a smart phone 130 displaying an interface that isassociated with the present invention. In particular, at least oneimplementation of the present invention, can communicate with the smartphone 130. Specifically, health data can be communicated with the smartphone 130 through an internet web page or through an applicationdedicated to communication with the present invention.

In at least one implementation, the webpage or the dedicated applicationcan receive data from the internet gateway 120. The data can be receivedeither through a connection to the internet or through a directconnection over the internal network. The webpage or dedicated softwarecan display, record, and save the oxygen and heart rate values.

This feature can allow the parent/caregiver to see the values inreal-time but also to be proactive in the parent's approach to healthcare. For example, the saved data can allow a caregiver to notice trendsin oxygen levels that could prove a useful method for detecting healthissues, such as sleep apnea and asthma. These trends can be identifiedin the form of graphs or history charts that display historical healthdata. Additionally, the data can also be a means for determining theamount and quality of sleep that the baby is getting. In particular, thesoftware may comprise a share feature that can enable a parent to easilyshare the health data with another, such as a doctor.

Additionally, upon receiving an alert generated by the receiving station110, or upon receiving health data that demonstrates a negative trend,the smart phone 130 can also indicate an alert. For example, the smartphone 130 can sound an audible alarm, vibrate, or generate a visualalert. One will appreciate, that there area multitude of methods forsmart phones 130 to alert a user, many of which can be used within thepresent invention.

FIG. 8 depicts a logical flow chart associated with implementations ofthe present invention. In particular, FIG. 8 depicts a logical treechart that describes an implementation of the logic that can be appliedto an abnormal reading of health data by software at the sensing module210, the receiving station 110, the remote computing device 130, or anyother computing device associated with the present invention. Ingeneral, an abnormal reading can consist of low oxygen levels or oxygenlevels above realistic values such as 100 and above. Additionally,abnormal readings also can represent a heart rate that is too high ortoo low. Further, abnormal readings can also consist of an absence of apulse oximeter reading or a bad pulse waveform. One will understand,however, that these are just potential reasons that an abnormal readingcan occur, and are not meant as an exhaustive list of the abnormalitiesthat the present invention can identify and compensate for.

Returning to FIG. 8, in block “a” an abnormal reading is detected. In atleast one implementation, upon detecting an abnormal pulse oximetryreading, the software can determine if an accelerometer 262 that is incontact with the infant is detecting motion. If movement is detected(block b-1), the abnormal reading can be moved to a lower priority,because a moving child is less likely to have a dangerously low oxygenlevel and movement may be a primary cause of abnormal readings. Inresponse to detecting motion, the software can generate a visualindication that an abnormal reading is being received, but that motionis being detected. For example, the software can generate a message on aremote computing device 130, or the software can display a visualindication on the receiving station.

In the case that abnormal readings continue, even if the softwaredetects motion, the software can enter an alarm delay mode (block d-1).In particular, the software can allow for a threshold amount of time forthe health readings to return to a normal level. The amount of thethreshold can depend upon the detected oxygen level and the upward ordownward trend. If after the threshold amount of time passes, the alarmis still producing abnormal readings (block e-1) then the software canraise the priority of the abnormal readings and signal an alarm. Forexample, the software can send an indication for an audible alarm (blockf-1) on the remote computing device or the receiving station. This alarmcan be a different alarm than the alarm used for a verified healthconcern. In particular, this alarm can be used to signify that theinfant may need attention, but is not likely in danger of a detectedhealth issue.

Returning now to box “a” in FIG. 8. If the software detects abnormalreadings and no movement is detected, the software can determine thestrength of the pulse oximeter signal. For example, the software candetermine that the signal from the pulse oximeter sensor is weak (blockc-2), that the actual pulse oximeter readings are unreadable, or thatthe pulse oximeter readings are questionable because of outsideinfluences. If the software determines that the signal is weak then thesoftware can indicate that an alarm be sounded (block d-2). In at leastone implementation, however, this alarm is different from the alarm thatis sounded if a health concern is detected. Specifically, this alarm canbe reserved for situation where an infant may need attention, but it isnot a health emergency.

In contrast, the software can determine that the signal from the pulseoximeter sensor is a readable signal (block c-3), or in other words,that the waveform and that SpO2 levels are clearly determined and thewireless signal is good. In this case, the software can indicate that avisual alert should be displayed. Similar to the visual alert describedabove, this alert can be displayed, for example, within a message on aremote computing device or within the display of the receiving station.

Also similar to above, the software can wait a threshold amount of timeto determine if the health data returns to normal (block d-3). If thethreshold time passes and the health readings do not return to a normalrange (block e-3), the software can indicate that an emergency alarm beindicated (block f-3). In at least one implementation, this alarm is thehighest priority alarm. Specifically, this alarm may be the loudestalarm and comprise a distinct sound.

In at least one implementation, this alarm may comprise an escalationprocess (block g-3). In particular, if the software does not detect aresponse to the alarm, the software can alert third parties, such asemergency responders or other designated individuals or devices. In atleast one implementation of the present invention, a user can customizethe priority and alarm that is associated with each of the abovesituation. For example, a user can specify that no alarm or indicationbe presented when abnormal readings are accompanied with the detectionof motion.

FIG. 9 illustrates a schematic diagram of another implementation of asystem for monitoring the health of an infant. In particular, FIG. 9depicts a sensing module 900 in communication with a variety of otherinfant monitoring devices for example, an audio monitor 910, a movementsensing pad 960 (including a wireless transmitter 920), a motiondetector 930, and a video monitor 950.

In at least one implementation of the present invention, an infantmonitoring system can include one or more of these devices incombination. For example, the sensing module 900 may detect an abnormalhealth reading. In response to the reading, the sensing module cancommunicate with the video monitor 950 and cause that a video stream orimage of the infant be transmitted to a remote computing device 130. Inthis way, a parent can receive a notification that an abnormal healthreading has occurred, while at the same time receiving an image of theinfant to help the parent determine whether the notification is anemergency.

Similarly, an implementation of the present invention can incorporatedata from the motion sensing pad 960, the motion detector 930, the audiomonitor 910, or the video monitor 950 to further investigate abnormalreadings. For example, in at least one implementation, in response toreceiving an abnormal reading from the sensing module 900, the audiomonitor 910 can be utilized to determine if the infant is making anysounds. Similarly, motion detection devices 960, 930, 900 can be used asdescribed above to further identify the appropriate alarm in response toabnormal readings from the sensing module 900.

Accordingly, FIGS. 1-9 provide a number of components, schematics, andmechanisms for wirelessly monitoring the health of an infant. Inparticular, in at least one implementation, a wireless sensorcommunicates health data from an infant to a remote computing device.The remote computing device 130 can then be used to monitor the infant'shealth or to alert an individual to a negative trend in the infant'shealth. Additionally, in at least one implementation, false alarms canbe detected, and in some cases prevented, by analyzing trends in thereceived health data. One will understand the benefits included withinan invention directed towards the above-described system.

The embodiments of the present invention may comprise a special purposeor general-purpose computer including various computer hardwarecomponents, as discussed in greater detail below. Embodiments within thescope of the present invention also include computer-readable media forcarrying or having computer-executable instructions or data structuresstored thereon. Such computer-readable media can be any available mediathat can be accessed by a general purpose or special purpose computer.

By way of example, and not limitation, such computer-readable media cancomprise RAM, ROM, EEPROM, CD-ROM or other optical disk storage,magnetic disk storage or other magnetic storage devices, or any othermedium which can be used to carry or store desired program code means inthe form of computer-executable instructions or data structures andwhich can be accessed by a general purpose or special purpose computer.When information is transferred or provided over a network or anothercommunications connection (either hardwired, wireless, or a combinationof hardwired or wireless) to a computer, the computer properly views theconnection as a computer-readable medium. Thus, any such connection isproperly termed a computer-readable medium. Combinations of the aboveshould also be included within the scope of computer-readable media.

Computer-executable instructions comprise, for example, instructions anddata which cause a general purpose computer, special purpose computer,or special purpose processing device to perform a certain function orgroup of functions. Although the subject matter has been described inlanguage specific to structural features and/or methodological acts, itis to be understood that the subject matter defined in the appendedclaims is not necessarily limited to the specific features or actsdescribed above. Rather, the specific features and acts described aboveare disclosed as example forms of implementing the claims.

The present invention may be embodied in other specific forms withoutdeparting from its spirit or essential characteristics. The describedembodiments are to be considered in all respects only as illustrativeand not restrictive. The scope of the invention is, therefore, indicatedby the appended claims rather than by the foregoing description. Allchanges which come within the meaning and range of equivalency of theclaims are to be embraced within their scope.

We claim:
 1. A system for wirelessly monitoring the a health of an infant, the system comprising: a sensing module removably disposed disposable within a wearable article, wherein at least a portion of the sensing module is configured to be in contact with the infant's foot; the sensing module comprising: a processing unit configured to receive and process health readings received by the sensing module, an accelerometer configured to detect movement of the infant's foot, the accelerometer also configured to determine a current sleeping position of the infant, wherein when determining the current sleeping position of the infant, readings from the accelerometer are allowed to settle and persist for a particular amount of time, and a pulse oximeter configured to detect at least a blood-oxygen level of the infant; and wherein the processing unit: identifies a particular alarm level based upon a health reading relating to the blood-oxygen level of the infant that was acquired during time periods when the accelerometer did not detect movement of the infant's foot, elevates the particular alarm level to a higher alarm level based upon a reading received from the accelerometer that indicates the current sleeping position of the infant is face down, and triggers an alarm alert at the higher alarm level.
 2. The system as recited in claim 1, wherein the processing unit is configured to: activate different combinations of photoreceptors and LEDs from a plurality of photoreceptors and LEDs within the pulse oximeter; and identify a particular combination that provides the a strongest relative signal.
 3. The system as recited in claim 1, further comprising: the pulse oximeter comprising a plurality of photoreceptors, wherein the processing unit is configured to activate each of the plurality of photoreceptors independently of each other and identify a particular photoreceptor of the plurality of photoreceptors that receives the a strongest relative signal.
 4. The system as recited in claim 1, further comprising: the pulse oximeter comprising a plurality of LEDs, wherein the processing unit is configured to activate each of the plurality of LEDs independently of each other and identify a particular LED of the plurality of LEDs that generates a strongest relative signal as received by a particular photoreceptor.
 5. The system as recited in claim 1, wherein the processing unit is configured to analyze raw pulse oximetry data and compress the data before the data is transmitted to a receiving station.
 6. The system as recited in claim 1, wherein a receiving station is configured to indicate an alarm when the processed health readings indicate a health trend that falls outside of a particular threshold.
 7. The system as recited in claim 6, wherein the processing unit is configured to disregard abnormal health readings that were detected during the a same time period that the accelerometer detected movement.
 8. The system as recited in claim 6, further comprising: a camera that is in communication with the receiving station, wherein the camera is configured to transmit an image when the processed health readings indicate a health trend that falls outside a particular threshold.
 9. The system as recited in claim 8, wherein the camera transmits an image to a mobile phone.
 10. The system as recited in claim 6, wherein the receiving station comprises software that processes received health readings from the a wireless transmitter.
 11. The system as recited in claim in 10, wherein the software is configured to identify false alarm trends in the received health readings.
 12. The system as recited in claim 1, further comprising: the sensing module comprising a vibrator that is configured to activate in response to abnormal health readings.
 13. The system as recited in claim 1, wherein the wearable article comprises a sock.
 14. The system as recited in claim 13, wherein the sensing module is removable from a pouch within the wearable article, such that the wearable article is washable.
 15. A method, performed at a processing unit in communication with a sensing module, for monitoring the a health of an infant, the method comprising: receiving data from the sensing module that is configured to be in contact with the infant's foot, wherein the received data comprises: motion data received from an accelerometer that is configured to be physically coupled to the infant's foot, wherein the motion data indicates movement by the infant, position data received from the accelerometer, wherein: the position data indicates a sleeping position of the infant, and the position data from the accelerometer is allowed to settle and persist for a particular amount of time when determining the sleeping position of the infant; heart data received from a pulse oximeter, wherein the heart data indicates cardiovascular biometrics associated with the infant; determining that a detected health data trend described by the heart data is outside of a threshold; elevating an alarm level associated with the detected health data trend to a higher alarm level based upon a reading received from the accelerometer that indicates a current sleeping position of the infant is face down; and triggering an alarm at the higher alarm level.
 16. The method as recited in claim 15, wherein determining whether the detected health data trend is outside of the threshold comprises determining that the detected health data trend remains outside of the threshold for a specific amount of time.
 17. The method as recited in claim 16, wherein determining that the detected health data trend is outside of the threshold comprises: receiving information from the accelerometer indicating that the infant is moving; and based upon the detected movement of the infant, tagging the data received from the sensing module.
 18. The method as recited in claim 17, wherein upon determining that the reported health data is outside the threshold and that the data received from the sensing module is tagged, determining that the reported health data comprises a false alarm.
 19. The method as recited in claim 15, wherein upon determining that the detected health data trend contained within the transmitted heart data is outside of a threshold, activating a vibrator that is integrated within the sensor module.
 20. A system for monitoring the a health of an infant, the system comprising: a sensing module that is configured to be in contact with the infant's foot, wherein the sensing module comprises: a processing unit configured to receive and process health readings received by the sensing module, an accelerometer configured to detect movement of the infant's foot, the accelerometer also configured to determine a current sleeping position of the infant, wherein when determining the current sleeping position of the infant, readings from the accelerometer are allowed to settle and persist for a particular amount of time, and a pulse oximeter configured to detect at least a blood-oxygen level of the infant; and wherein the processing unit: identifies a particular alarm level based upon the blood-oxygen level of the infant, elevates the particular alarm level to a higher alarm level based upon a reading received from the accelerometer that indicates the current sleeping position of the infant is face down, and triggers an alarm alert at the higher alarm level.
 21. A system for wirelessly monitoring the a health of an infant, the system comprising: a pulse-oximetry sensing module removably disposed disposable within a wearable article, at least a portion of the sensing module is configured to be in contact with the infant's foot; the pulse-oximetry sensing module comprising: a processing unit configured to receive and process health readings received by the sensing module, an accelerometer configured to determine a current sleeping position of the infant, wherein when determining the current sleeping position of the infant, readings from the accelerometer are allowed to settle and persist for a particular amount of time, and a pulse oximeter configured to detect at least a blood-oxygen level of the infant; and wherein the processing unit: generates a particular alarm level based a health reading relating to the blood-oxygen level of the infant, elevates the particular alarm level to a higher alarm level based upon a reading received from the accelerometer that indicates the current sleeping position of the infant is face down, and triggers an alarm alert at the higher alarm level; a wireless transmitter in communication with the processing unit and a receiving station; and the receiving station comprising a display. 